DE2734292C3 - Arrangement for voltage control - Google Patents

Description

The invention relates to an arrangement / ur voltage control with an alternating current carrying working winding and a control winding Transductor and a transformer, in which the transductor and the transformer are on a common Kern / ti of a unit are combined.

The principle of a transducer has long been known, but only the increasing automation in the last line made it ever more important.

The main ingredient one. Traiisduktors is one Throttle, consisting of a: '' Sihlossenen liscnkein without air gap with one or more windings. As will be explained in more detail later. are mostly several files in pairs / interconnected. AK other components still come rectifier hm / u.

Characteristic of an I r; ins <liiktor are his high operational reliability, its long service life and the high gain factor. However, that stands for his relatively large weight, its inertia in control and the relatively high price for the magnetic core material opposite.

In most cases, the output voltage of the transducer must match the input voltage of the Be adapted to the unit. As is known, this is done using an additional transformer. But now we know the transformer itself is also relatively heavy; in addition, there is the relatively high price for the core material.

From DE-AS 23 43 815 it is known, in a transductor circuit arrangement, which consists of two transductor chokes with one work and one control winding each, the consumer-side output of which is from one AC voltage source at the input of the transducer circuit arrangement is galvanically isolated, is formed, the transducers and the output transformer in to combine a transductor-transformer unit. Compared to one of the individual components formed arrangement for voltage control, such a unit has a very much lower weight and a volume only slightly larger than that of a single transformer. However, she has one relatively complicated structure.

The invention is based on the object of a To create an arrangement for voltage control of the type mentioned, which is very simple and is set up in a straightforward manner.

This object is achieved according to the invention in that the core has two adjacent, has the same narrow and two adjacent wide legs, and that on the two narrow ones Legs the control winding, on the outer, wide leg a co-wound, Alternating current-carrying secondary winding and one in opposite directions on the wide leg in between wrapped, change! introducing primary winding are arranged.

This creates an arrangement with a simple structure, which is in a magnetic unit comprises both a transducer and a transformer. As a result of the small volumes of iron and Copper results in correspondingly lower losses. The arrangement according to the invention shows a considerable Improved dynamic control behavior: Line only causes a slight change in the controlling current an immediate change in the power flow linked to the secondary winding and thus an immediate change in the output voltage to be controlled.

Further features and refinements of the invention are characterized by the subclaims.

The invention is explained in more detail below with reference to exemplary embodiments in the drawing; it show in schematic representation

F i g. 1 shows the electrical circuit diagram of a known arrangement with a transducer and a transformer;

K ig, 2 a core of the crfindiing ^ cmalten arrangement:

I · 'i g. 3 (lic arrangement according to the invention with one Core winding;

F i g. 4 the arrangement according to the invention with two identical Stciierwickliingen.

According to Fig. I in the M denotes a transductot to which a transformer TT for voltage

adaptation to the unit to be fed is attached. The transducer 71 is made up of two chokes D I and D2 , each with a working winding W1 and W2 and a control winding W3 and W 4 as well as rectifiers 1 and 2. The output side of the transducer TI and the load resistor in series are connected to a sinusoidal AC voltage that is applied to terminals 3 and 4. The transformer 72 for voltage adjustment has a primary winding W5 and a secondary winding W6, the primary winding WS being connected as a load resistor for the transducer 71. Each of the chokes D 1 and D 2 is designed so that it can fully absorb a half-wave of the AC mains voltage. The core saturation can be changed by means of a controlling direct current applied to terminals 5 and 6; the controlling direct current defines the operating point on the magnetization characteristic or hysteresis loop.

The transducer 71 is biased by the controlling direct current to a defined point in the hysteresis loop. At the beginning of the first half-wave of the sinusoidal alternating mains voltage, a current initially flows which has not yet caused any reversal of magnetization, so the choke D 1 does not yet absorb any voltage. Then the magnetizing current increases and the inductor D 1 is magnetized. If saturation is reached, the choke Di can no longer take up any voltage. A current then flows through the working winding W1 or W2, which results from the magnitude of the mains AC voltage and from the load resistance W5.

The current through the choke D 1 now follows the sinusoidal line of the AC mains voltage until the upper left corner of the hysteresis loop is reached. Then the reverse magnetization of the choke D 1 takes place and at the same time the remagnetization of the choke D 2, which has reached saturation in the defined starting point in the hysteresis loop.

The current flowing in the primary winding WS of the transformer 72 results from the composition of the inductor currents. The output voltage of the transformer 72 on the secondary winding W6 at terminals 7 and 8 can therefore be controlled by the magnitude of the direct current applied to the terminals 5 and 6.

According to FIG. 2, 9 denotes a transformer core. The transformer core 9 has two adjacent, identically designed, narrow legs 101 and 102 and two adjacent wide legs 11 and 12. The transformer core 9 is preferably made of a conventional three-phase transformer core formed with three identical legs 10, II and) 2, one of the outer legs, im Example of the leg 10, divided into two identical narrow legs 101 and 102.

According to FIG. 3, a primary winding W7 is applied to the middle limb 11 of the transformer core 9 and a secondary winding WS wound inwardly to the primary winding is applied to the outer limb 12. A control winding W9 which is also wound in opposite directions / primary primary winding W7 is applied to the legs 101 and 102. The Stcucrwickking W9 is wrapped around the legs 101 and 102 in the shape of a figure eight, as shown in FIG. i is symbolically represented by the ge / .cichn <menu turns. A direct current can be applied to the safety winding W9 via terminals 15 and 1h. The mains / alternating voltage can be applied to the primary winding W7 via terminals 17 and 18. Via terminals 19 and 20, the output voltage adapted to the feeding unit can be taken from the secondary winding Wrf. The rectifiers provided according to FIG. 1 are omitted.

Numerical example

A commercially available three-phase Tratis-

Ki formator core with a length of 190 mm and a height of 190 mm. the three legs 10, 11 and 12 are each 38 mm wide and at a distance of 38 mm from each other arranged. The yoke width is 38 mm in each case; d. H. the leg length is 114 mm. The leg is OK

ίο in two equal legs 101 and 102 with one each width of 7 mm divided. The control winding W9 has about 500 turns, the primary one Winding W7 has approx. 480 turns on the secondary winding W8 has approx. 60 turns.

The AC mains voltage of 220 V is applied to the primary winding 1V7, the output voltage is approx. 15 V.

An arrow 21 in the leg 11 symbolizes the direction of the magnetic flux that is caused by the current flow in the primary winding W7, referred to in the following as the primary flux Φ PR , during the positive mains voltage half-wave. Furthermore, an arrow 22 in the leg 12 symbolizes the direction of the magnetic flux

j (i ses, which is caused by the current flow in the secondary winding W8, referred to in the following as the secondary power flow Φ SE , during the positive mains voltage half-wave.

When there is no direct current through the control winding

π W9 flows, if neglected the Scatter of the primary power flow on the closed iron path in

Φ PR = φ SE + Φ ST.

where the power flow Φ STate power flow in the legs ICi and 102 is defined with the same direction and the same strength (arrows 23 and 24). The secondary voltage USE , which is proportional, is induced by the power flow Φ SE passing through the secondary winding W7

d Φ SE

ie for a given period the induced secondary voltage USE can be set proportional to the power flow Φ SE. The induced voltages in the winding W9 cancel each other out due to its special winding shape.

If now a direct current through the Sieuerwickel W9 flows, the result is infoige of the Gkichstromvorm .: gnetisierung a static flow state, as indicated by the dash-dotted line 25 in F i g. 3 is shown.

During a positive AC voltage half-wave Airken then in the leg 102 the power flow Φ .S'7 (arrow 24) and the static flow in the same direction and in the handle 101 the power flow Φ ST and the static flow in the opposite direction, so that the magnetic resistance in Leg 102 is larger than that in leg 101. Due to this imbalance of the magnetic resistances in legs 101 and 102, an alternating spindle is created in control winding W9.

half-wave positive l'oliiriliit indii / ierl. click around the winding entrance. As a result of the greater magnetic resistance of the leg 102, the primary kniffliiB '/' PR is also imparted in such a way that the secondary power flow '/' .S7: 'increases and the power flow' / '.S7' increases. But if the power flow '/> .S "/:' increases, the secondary voltage ILSf: at the output also increases immediately.

In the negative Nct / weehsclspannungshalbwcllc • The directions of action of the force flows change. this means that the magnetic resistance in the leg 101 is then correspondingly greater than that in the Leg 102. The alternating voltage half-wave induced in the control winding W 9 consequently has the same Polarity as in the positive idle wave of the mains alternating voltage. This simplifies the sehaltungstechni see effort in the Steticrkreis considerably. About that In addition, with a defined control voltage value, the DC voltage level can be provided correspondingly lower because the control voltage of the control winding IV9 with voltage half-waves in each half-wave positive polarity is applied.

In this way, the output voltage can be controlled in both half-waves of the mains input voltage will.

Dm the via terminals 15 and 16 into the DC source feedback voltage wave wedge to reduce, can in the DC feed a small coil /. I (Fig. 3) can be provided.

The control in the arrangement according to the invention is compared to that in the known arrangement according to fig. 1 is more precise and responds much more quickly: Only a slight change in the direct current flowing through the control winding IV9 causes an immediate change in the secondary power flux Φ SE, which is linked to the turns of the secondary winding VV8. and thus an immediate change in the output voltage.

The arrangement according to FIG. 4 differs from the one according to FIG. 3 with regard to the arrangement of the control winding: The slewing winding VV9 is divided into two identical windings W 10 and VVII, and each of the narrow legs 101 and 102 is provided with a winding W 10 and IVII, respectively. The control windings IV 10 and VVIl are in turn wound gcgensinnij to the primary winding IV7 or in the same direction to the secondary winding VV8. The Slciicrwick hung W 10, IV 11 are either parallel or, like those in F i g. 4 is shown. connected in series. Dc current flow through the control windings IVIO. IVIl can be changed by a resistor 26.

Since the magnetic path for the Steiierwickei H 10. IVII is arranged parallel to that of the secondary winding IV8 and is therefore of the same length, the magnetic voltage must also - that is the proportion of the total ampere-turns that lie on the magnetic path under consideration - .the wire needed to generate a power flow in the legs 101 and 102 of the magnetic .Connect voltage, the n \ Frzeugung when the hole lengths are considered in terms of dl · .Schenkellängen small as equal to a Kraftflusscs in the SCH, nkcl is benötig 12 as is the case in the example. If a low alternating voltage is applied to the primary winding IV7 via terminals 17 and 18, then cmc voltage is induced in each of the secondary windings VVIO and VVII. The current flow through the control windings IV Y-j and IVM can be changed by the resistor 21. If, for example, the current through the control windings IV10 and WlI is increased by means of the variable resistor 26, the current flowing through the primary winding VV7 also increases and so does the magnetic voltage in the leg 11 12 and thus the current through the secondary winding IV8 or the output voltage applied to terminals I 'and 20. The value of the output voltage can thus be controlled by the value of the current set by means of the resistor 26.

Claims (6)

Patent claims: 1. Arrangement for voltage control with an alternating working winding and a control winding having transductor and a transformer in which the transductor and the transformer are combined on a common core to form a structural unit, characterized in that the core in two adjacent, same narrow and has two adjacent wide legs, and that on the two narrow legs the control winding, an alternating π wound in the same direction on the wide outside leg current-carrying secondary winding and one in opposite directions on the wide leg in between wound, alternating current carrying primary winding are arranged. 2. Arrangement according to claim 1, characterized in that the core may be a three-phase transformer core is formed with three equal legs, one outer leg in two equal narrow legs is divided. 3. Arrangement according to claims 1 and 2, 2j characterized in that the individual turns of the control winding in Fo; In an eight to the both narrow legs are wrapped. 4. Arrangement according to claims I and 2, characterized in that the control winding in "1 two equal windings and each winding is divided handle each wound in the same direction to secondary winding around a narrow ^r?. and that the two identical windings are connected in series with one another and a π current-setting element is arranged in parallel therewith. 5. Arrangement according to claims I and 2. characterized in that the control winding in two equals windings split and each winding in the same direction as the secondary in Winding is wrapped around a narrow leg. and that the two identical windings to each other and are connected in parallel with a current-generating element. 6. Arrangement according to claim 4 or 5. characterized j-, characterized in that the Stromstellcndc member is designed as a variable resistor.